A Polynuclear Tetracarbonyl Hydride of Rhenium. Preparation and

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POLYNUCLEAR TETRACARBONYL HYDRIDE OF RHENIUM

Nov. 20, 1964

"v

as a catalyst in facilitating decoinposition of dicobalt octacarbon yl. The following generalized equation may be written for the displacement of primary alcohols from the dicobalt octacarbonyl-alcohol complex with water.

CS(CO)* CiHvOH

? 00

+ HOH e [ C o ( C O ) j H O H ] ' [ C o ( C O ) ~ ] -+ ROH

[Co(CO)4HOH] +[Co(CO),] -

[ CO(CO)jKOH] - [ CO(CO),]

(8)

The limitation placed upon the exchange reaction given in eq. 8 is t h a t the alcohol complex be reasonably watersoluble for the displacement of the alcohol to occur. Thus, it is possible t o interchange low molecular weight straight-chain primary alcohol complexes, such as methanol, ethanol, 1-propanol, and 1-butanol, quite readily with water. The exchange reaction with water becomes slightly more difficult as the carbon number increases in the series. However, when we reach 1pentanol, the solubility of the dicobalt octacarbonyl complex in water is quite low, and by the time the carbon number in the alcohol complex reaches six, it is insoluble in water. I t was previously concluded that the inability to simply water extract dicobalt octacarbonyl from the 1octanol complex was due to the high water insolubility of this complex. To check the validity of this conclusion, reactions between dicobalt octacarbonyl and excess 1-butanol were studied. Since 1-butanol is far more soluble in water than 1-octanol, one might predict a simple water extraction of the 1-butanol complex to be feasible. Indeed. this appears to be the case. The results of extracting this complex with water, or a watermethanol solution, are shown in Fig. 1. As noted from the graph, a simple water extraction was found to be quite effective since 83y0of the cobalt ion was extracted into the aqueous phase. The addition of very small amounts of methanol (ca. 0.5 vol. yG)does appear to improve the water-extraction process slightly by about 10%. Both the 1-butanol and the aquo complex of dicobalt octacarbonyl appear to be fairly water-soluble. The major ligand-exchange reactions, which are probably occurring in this system a t low temperatures, may be represented as [CONTRIBUTION KO. 1628 FROM

THE

484 1

It may also be noted from Fig. 1 that large quantities of methanol are detrimental to the water extraction of dicobalt octacarbonyl from the 1-butanol complex.

0

Fig

IO

20 30 40 50 60 [METHANOL], VOLUME P E R C E N T

70

1.-Extraction of [Co(CO),(C 4 H ~ 0 H +, )] [CO(CO)~(CH~OH)] -, and [Co(CO)d]- by methanol-water mixtures

This occurrence is not surprising since the system is approaching that of a homogeneous solution rather than remaining a two-liquid-phase system. I t has been observed in this work that the extraction of dicobalt octacarbonyl-alcohol complexes with a water-methanol (70.5 vol. %) solution is more applicable and effective when high molecular weight, primary alcohols, such as 1-heptanol, 1-octanol, or 1-decanol, are complexed to dicobalt octacarbonyl. Acknowledgment.-The authors wish to thank M r . H . J . Elder for preparing the dicobalt octacarbonyl, Drs. W. E . Mott and H . A. Braier for their helpful suggestions and assistance with the radiorheniical experiments, and Miss E . L. Derusha for performing the cobalt carbonyl analysis.

DEPARTMENT OF CHEMISTRY, USIVERSITYOF CALIFORNIA, Los ANGELES,CALIFORNIA 900241

A Polynuclear Tetracarbonyl Hydride of Rhenium.

Preparation and PropertieslaZb

BY D. K. HUGGINS, W. FELLMANN, J. M. SMITH,A N D H . D. KAESZ RECEIVED JUXE20, 1964 The preparation and properties of a new polynuclear carbonyl hydride of rhenium are reported. The compound is isolated from the treatment of Ren(CO)K with excess iYaBH4 in tetrahydrofuran with subsequent acidification in the presence of cyclohexane. The compound is colorless, crystalline, and diamagnetic; molecular weight and analyses fit the formula [HRe(CQ)4]3 Infrared spectra of this compound and its deuterated derivative, in the region 3000-290 cm are presented and discussed The compound is believed to be analogous t o a derivative of technetium, reported earlier from these laboratories, with which it is isomorphous in the crystalline state.

Introduction A polynuclear tetracarbonyl of T c was recently reported2 which was obtained as a by-product in the syn(1) (a) This work has been supported b y G r a n t No. GP 1696 f r o m t h e Kational Science F o u n d a t i o n ; ( b ) Paper No. 2 8 , Symposium o n Metal Carbonyls and Related Complexes, 147th National Meeting of t h e American Chemical Society, Philadelphia, P a . , April, 1964.

thesis of H T C ( C O ) ~ .We ~ have now discovered what we believe to be an analogous derivative of Re which we have been able to isolate from the same reaction sequence' Our first preparation O f the polynuclear (2) H . D . Kaesz and D. K . Huggins, C a n . J . C h e m . , 41, 12.50 (1963). (3) J. C. Hileman, D. K . Huggins, and H . D. Kaesz, l n o v g C h e m . , 1, 933 (1962).

4842

D. K. HUGGINS,W. FELLMANN, J. M. SMITH, A N D H. D. KAESZ

tetracarbonyl of Re followed essentially the same procedure as described for the compound of Tc,' with one exception: since it was more difficult to bring about CO cleavage from Re2(CO)lothan from Tc2(CO)lo, it was necessary to warm the reaction mixture (tetrahydrofuran solution in contact with Na-Hg) to reflux in the initial step. The yields, however, were low. Since there had been reports of the action of NaBH4 on Mnz(CO)lo,4or Fe(CO)5,jto form lower carbonyl hydrides or carbonyls, we were prompted to try this reagent instead of Na-Hg in the initial step. After acidification, we obtained the same product but in greatly increased yields. e& '\ will therefore describe the synthesis of the polynuclear tetracarbonyl of Re by the S a B H 4method. In order to establish whether our derivative contained hydrogen and a t the same time identify any bands which might be associated with vibrations involving that atom, a deuterated derivative was sought. An attempted exchange of protons by treatment of the rhenium derivative with the mixed solvent system D20tetrahydrofuran (3% D20by volume) led to a recovered product which had an identical infrared spectrum with the starting material. A more vigorous chemical transformation, however, was found to be successful. The similarity of the product obtained through the deuteration cycle with the original product was ascertained through a comparison of X-ray powder diffraction spectra.

Experimental All operations during the synthesis of the carbonyl derivative of Re were carried out under an inert atmosphere; while the final product turned out to be air stable, certain of the intermediates were decidedly not. Preparation of a Polynuclear Tetracarbonyl of Re.-In a typical preparation, Res(CO)lo (2.0 g., 3.07 mmoles) and NaBHl (1.6 g., 42.2 mmoles) were dissolved in 50 ml. of tetrahydrofuran (dried over CaH? and redistilled under IV,) and stirred with reflux for 1 hr. The solution turned yellow a t first, then orange, and finally red, with gas evolution. After cooling t o room temperature, the S a B H 4 was allowed t o settle and the solution was decanted from the solids. The solvent was evaporated under reduced pressure, and the resulting solids were pumped under high vacuum for 2 hr. (30-36") t o remove final traces of solvent. Cyclohexane (80 ml., redistilled from CaH2 under Nz) and sirupy H a P 0 4( 10 ml., stripped of dissolved O2 by prolonged bubbling of N2 and treatment with a few drops of Sa-Hg) were then added over the solids. The heterogeneous system was refluxed for 2 hr. (Optimum yields of the desired product are obtained only upon prolonged heating as in the liquid-liquid extraction step, mentioned below.) Infrared spectra in the carbonyl stretching region of the cyclohexane solution before reflux showed the presence of a number of unidentified bands which could belong t o some precursor t o the desired product. We believe we have isolated such an intermediate in the form of yellow crystals which are under study. The heterogeneous system was then subjected to liquid-liquid extraction with hot cyclohexane until the supernatant liquid over the phosphoric acid solution no longer showed the presence OF product. Upon cooling, colorless crystals were obtained from the mother liquor which were separated and recrystallized from cyclohexane once or twice t o give essentially pure product; yield 850 mg., or 46(:< based on Re?(CO)lo. Anal. Calcd. for the etnpirical formula [HRe(CO)a] R e , 62.23; C , 16.05; H , 0.34. Found: Re, 61.12; C , 16.04; H , 0.30.fi Confirmatory evidence for the presence of H was obtained from the infrared spectra of deuterated material (see below). ,t:

(4) W'. Hieber, W. Beck, and G. Zeitler, A n g e w . [ h e m . , 73, 361 (1961). (a1 I). T. Haworth and J , R. Huff, J . I n o v g . S u c l . C h e m . , 17, 184 (1961).

(6) Special precautions were taken t o increase accuracy in analysis for H. Solvent was pumped away for a prolonged pet-iod under vacuum; contact with filter papei- and other possible contaminants containing hydrogen was avoided, and blank runs were performed before a n d a f t e r the analyses t o determine background, if any. Analyses were performed by t h e Schwarzkopf Microanalytical Laboratory, Woodside. N. Y., and by Miss Heather King of this department.

VOl. 86

Preparation of a Deuterated Derivative.-.4 quantity of trimer (500 mg.) was treated with sodium amalgam in tetrahydrofuran under inert conditions which resulted in a slightly pale yellow solution whose infrared absorptions no longer resembled the pattern of the original product. Then solvent was removed, cyclohexane brought in, and the mixture acidified with sirupy DaPOa (99y0 pure, as prepared from D 2 0 and P206,7aand checked by n.m.r. for residual protons7h). After a brief period of reflux t o bring the formation of trimer to completion, a product was extracted from the heterogeneous mixture and recrystallized. I t is possible t o achieve recovery of 347, of the deuterated product; most of the losses, we feel, are incurred through handling of the small amounts reported here. The product was analogous t o starting material; it had the molecular weight of a trimer and an X-ray powder pattern closely resembling starting material (see below). Also, infrared absorptions (discussed below) showed certain significant differences which could be attributed only t o the presence of hydrogen in the original product which was replaced by deuterium by the chemical treatment mentioned above. The deuterated product did not exchange with protons in air or even in the mixed solvent water-tetrahydrofuran. Molecular Weight Measurements.-On account of the very low solubility of our new derivative in the normal solvents, we found it necessary t o calibrate our instrument for the concentration range in which our unknown was found to lie. We used a Mechrolab vapor pressure osmometer, with cyclohexane solutions, and benzil a s a standard. Curiously enough, our derivatives of rhenium were even less soluble in benzene than in cyclohexane. Our d a t a are presented in Table I .

TABLE I MOLECULAR WEIGHTDATA Compound

Concn.," mg./g.

AR (a".)! ohms

Molality X 10'

----Mol. Obsd.

wt.Calcd.

Benzil 5.400 10.47 2 5 . 7 210.23 Benzil" 1.080 2.30 5.14 210.23 Benzil" 0.540 1.25 2.57 210.23 210 23 Benzil' 0.1080 0 . 2 5 0 , 5 1 4 Rhenium tetracarbonyl 1 . 4 0 917 f 50 8 9 7 . 8 0.64 hydride trimer 1,285 0.62 1.33 9b8 f 50 901.8 Deuteride trimer 1.247 685zk40 652.5 0.87 1 . 9 RedCOhod 1.300 Cyclohexane solutions; for greatest accuracy, solutions were made up by weight using an analytical balance. Owing to the evaporation of solvent over longer periods of time on storage in ordinary volumetric flasks, solutions were utilized immediately after they were made. T h e average represents five or more readings, taken only when t h e instrument was observed to be stable, t h a t is, when the deviation within the readings was no more than =tlyGfor concentrated solutions, or up t o 5570 on the most dilute samples. Obtained by dilution of first listed sample. Measured a t these high dilutions expressly for the purpose of comparing with unknown, at the operating limits of the instrument. Magnetic Susceptibility .-An early determination of t h e susceptibility of the trimer was carried out with a 90-mg. sample by M r . Peter Wooliams on a Gouy microbalance a t the Chemical Laboratories of University College, London, through the kindness of Professor R . S.Nyholm. The measurements showed that the compound was essentially diamagnetic, though under several different packings slight pulls were nevertheless observed. Owing t o the stability in air of our derivatives, we had purified the sample without precautions to exclude oxygen. These results therefore led us to attempt a further purification under an inert atmosphere, leaving us finally with a highly purified sample, but of greatly reduced weight. I t was necessary to make use of an instrument on which samples of about 1 5 2 0 mg. could be meas~~

(7) (a) N. N. Greenwood and A. Thompson, Inorg. Syn., 6, 81 (1960). (b) T h e analysis was performed by adding precisely known amounts (by weight) of HlPOl ( 8 5 % , Baker and Adamson analyzed reagent grade) t o t h e sample a n d plotting the total signal amplitude against added protons on the Varian A-60 nuclear magnetic resonance spectrometer. Extrapolation t o zero signal gives t h e amount of protons originally present, similar t o the analysis of D20; cf. "This is N M R a t Work," advertisement series of Varian Associates No. 57, which appeared on t h e back cover of J. A m . Chem. Soc., and occasionally other journals, or available directly from t h e manufacturer in "Technical Information Bulletin," Vol. 2 . No. 4, 1959.

POLYNUCLEAR T E T R A C A R B O HYDRIDE NYL OF R H E N I U M

Nov. 20, 1964

4843

TABLE I1 DATAFOR MEASUREMENT O F MAGNETIC SC'SCEPTIBILITY FOR

Temp, OK

Wt o u t of field, mg

W t in field. mg

RMS deviation, mg

Av difference, mg

Difference, mg

THE

TETRACARBOXYL HYDRIDE TRIMER OF Re"

Corr. av. wt. difference, mg.

Diamagnetic' corr.

Sample wt.. mg.

dH

xH 0 0 0 0 0

8784 8778 8783 8785 8777

-0

0 0 0 0 0

8878 8927 8975 9010 9100

- 0 0487

0488

1 0 0004

=to 0006

+ O 0491 (10.0002)

f O 0003 ( 1 0 0006)

12 754

f0.0491

+ O 0004 ( 1 0 0008)

12 754

(fO 0002)

I-): .(

d,

X

2 3 X 10-6

XQ

+ O 006 ( 1 0 012

2 512

3 1 X 10-5

x x

+ O 008 X

2 512

( i o 016

10-0

10-1)

10-8

X 10-6)

0 Obtained through the courtesy of Professor T. S. Piper, Department of Chemistry, University of Illinois, Urbana, Ill ; measurements Correction for sample bucket. carried out a t the University of Illinois by Mr. David Lloyd, whose help we gratefully acknowledge. c From measurements on standard, Ni( NH4)2(SO4)z. 6 H 2 0

'

TABLE 111 X - R A YDIFFRACTION DATA --Res(CO)izHu

. ,-RedCO)izDs--

8.124" 7.583 7.213 6.794 6.758 6.554

(l)* (2) (10) (2) (2) (2)

5.651 4.062

(3) (1)

3.590

(1)

3.484 3.473 3.377

(2) (1) (1)

3.149 3.037 3.032 3.013 2.932 2.860

(2) (2) (2) (2) (1) (2)

2.028 2.023 1.972 1.967

(2) (2) (1) (1)

8.162" 7.634 7.237 6.794

(2)' (4) (10) (3)

6.549 5.890 5.669 4.069 3.959 3.600 3.587 3.484 3.420 3.376 3.335 3.255 3.150 3.036

(3) (2) (4) (2) (2) (2) (2) (3) (1) (1) (2) (2) (3) (4)

2.938 2.863 2.378 2.249 2.130 2.030

1.624

a

d-Spacings.

* Visually

7osdco)lz--

(2) (2) (2) (1) (2) (2)

(1)

7 7 7 6 6 5 5 4 4 3 3 3 3 3 3 3 3 3 2 2 2 2 2 2 2 2 2 2 2 1 1 1 1

381" 219 031 779 607 491 173 303 075 798 577 431 357 292 220 211 166 015 953 905 i71 739 696 557 532 242 159 128 098 977 905 889 873

(2)* (9) (9) (3) (5) (10) (1) (1) (1) (3) (1) (2) (2) (1) (1) (2) (1) (2) (6) (1) (3) (2) (1) (1) (2) (1) (1) (1) (1) (1) (3) (1) (1)

estimated intensity

ured, and this was kindly made available t o us by Professor Piper of the University of Illinois. T h e results of the determination, performed on a Faraday* microbalance, are presented in Table 11. The observed susceptibility given in the last column of the table is small, positive, and temperature independent in the range studied. T h e results for the highly purified sample essentially bore out the observations on the initial sample, so only the d a t a for the former are presented here. Molecular diamagnetism is characterized by a small susceptibility, is temperature independent, and may have either a negative or a positive value.9 By estimating diamagnetic corrections (8) W . E. Hatfield, R . C. F a y , C . E . Pfluger, a n d T . S. Piper, J . A m . Chem. SOC., 86, 265 (1963). (9) P. W . Selwood, "Magnetochemistry," Interscience Publishers, I n c . , New York, N . Y . . 1956, p. 83.

from the best available information t o date (which is none too good for atoms or groups of atoms in carbonyl derivatives), we would predict a susceptibility of x g = -0.254 X 10-6.io When subtracted from the observed susceptibility this leaves a net residual paramagnetic susceptibility xgm" = +0.260 X The compound therefore does not possess any unpaired electrons and may be termed essentially diamagnetic. Also, a tally of electrons around the metal is consistent with the effective atomic number rule of Sidgwick.

R4WPI

A

I

I)

B

m

I

,

L X

I

1

,

.

,e, CU-K.

a

.

,

m

5

I

c

s

Fig. 1.-X-Ray powder patterns: Re3(C0)]2H3( a ) product obtained from original reaction mixture; ( b ) pioduct obtained from chemical cycle like t h a t used for deuteration, but with H 3 P 0 4 in the final step; Res(C0)12D3, product obtained from deuteration cycle, 999; D, in the final step; OSS(CO)I,, structure previously determined, see ref. 11. X-Ray Powder Patterns.-In order t o ascertain the similarity of original product with t h a t which was produced through a deuteration cycle, we obtained X-ray powder patterns. These are shown in Fig. 1 and the d-spacings listed in Table 111. X pattern for o s 3 ( c o ) L 2 , 1a 1compound we believed might be structurally related t o our derivatives, is also included. These were obtained through the courtesy of Professor W. Gary Ernst of the Geology Department of this University, with the aid of Mrs. Eva \.ary, whose help we gratefully acknowledge. Spectra were taken on powders mounted on glass slides; a Sorelco X-ray diffraction unit was utilized with Cu KQ radiation and NaCl as a standard. Infrared Absorptions .-We scanned the region 4000-290 cm. -' in the infrared for the two derivatives using a combination of instruments. The maxima observed are listed in Table 11'. In the region 4000-400 c m - l it was convenient to scan the samples in KBr pellets; these are shown on Fig. 2. This was accomplished on a Perkin-Elmer 421 spectrophotometer, equipped

-

estimated by extrapolation of d a t a from (10) xa(Ke-l) -0.27 X ref. 9, p. 78, and by Korol'kov's method, c ~ f , ,Ciwm. Abslv , 6 7 , 4:316! ( 1 9 6 2 ) . xn(H-') -9.9 X 10-8, W . Klemm, "Xlagnetochemie." Akademiwhe Verlag, Leipzig, 1936, p . 150, and x n ( C O ) -0.l.W x l o - " , from Pawal'q constants (11) T h e sti-uctui-eof thiscompound has been reportrd b y E.I